Measuring instrument



April 6, 1943- E. c. WIEGMANN ETAL MEASURING INSTRUMENT Filed Dec. 2, 1938 7 Sheets-Sheet l oi O FlG. 2.

INVENTOR. WALTER G. TRUMBOWER COLEMAN B. MOORE EDWIN c. wneemwu BY Q W \L ATTORNEY.

April 1943. E. c. WIEGMANN EFAL 2,315,682

MEASURING INSTRUMENT v Filed Dec. 2, 1938 7 Sheets-Sheet 2 INVENTOR.

WALTER G. TRUMBOWER COLEMAN B. MOORE y EDWIN amzcmuu ATTORNEY April 1943. E. c. WIEGMANN HAL 2,315,682

MEASURING INSTRUMENT Filed Dec. 2, 1938 TSheets-Sheet 5 INVENTOR. WALTER G.TRUNBOVIIR COLEMAN a. MOORE y eowm cmssmuu I ATTORNEY E. C. WIEGMANN ETIAL MEASURING INSTRUMENT Filed Dec. 2, 1938 a 7 Sheets-Sheet 4 INVENTORY WALTER G. TRUMBOWER COLEMAN B. MOORE y EDWIN C. WIEGMANN A TTORNEY April 6, 1943. a. c. WIEGMANN EI'AL. 1

' mmsunma INSTRUMENT Filed Dec. 2, 1938" I 7 Sheets-Sheet s Fuse.

2 VENTOR WALTER G. TRUMBOWER COLEMAN B. MOORE BY swafimssmuu I ATTORNEY E. C. WIEGMANN ETAL MEASURING INSTRUMENT A ril '6, 1943.

Filed Dec. 2, 1958 'TSheets-Sheet 6 FIGS.

I09 FIG. IO. I08 I 4 III y n2 24'wp B 9 I U H3 III III! llll IHI Illl Hll HH HH H11 H11 Ill INVENTOR.

WALTER G.TRUMBOWER COLEMAN B. MOORE BYR Esaifl CJVIEGHANN ATTORNEY t p 1943- E. c. WIEGMANN ETAL $315,682

MEASURING INSTRUMENT Filed Dec. 2, I938 '7,Sheets-Sheet '7 FIG. l2.

Patented Apr. 6, 1943 MEASURING INSTRUMENT Edwin C. Wiegmann and Walter G. Trumbower, Philadelphia, and Coleman B. Moore, Carroll Park, Pa., assignors to The Brown Instrument Company, Philadelphia, Pa., a corporation of Pennsylvania Application December 2, 1938, Serial No. 244,152

Claims.

The present invention relates to potentiometrio instruments and more particularly to a means for automatically recalibrating or standardizing such an instrument at suitable intervals to compensate for variations in the source of voltage which is used to energize the potentiometer.

More particularly it is an object of the invention to provide a mechanism which will utilize the automatic rebalancing mechanism of a potentiometer, after a suitable number of rebalancing operations, to periodically recalibrate the instrument to thereby maintain its readings at the highest possible accuracy. Provision is also made whereby the instrument may be standardized at any time between the regular standardizing periods.

The mechanism of our invention may be used with equal facility upon instruments that are adapted to record the value of a single variable or the values of a plurality of variables. In the latter case provision is made to prevent a recording operation from takin place during the recalibrating periods so that a false reading will 'not be obtained.

The mechanism of our invention may readily be placed either in new instruments or in instru- --.ments which are already in use by the mere substitution of one assembly for another and the addition of a drive lever or gear to the mechanism of the potentiometer, for the assembly.

The various features of novelty which characterize our invention are pointed out with particularity in the claims annexed to and forming a part of this specification. For a better understanding of the invention, however, its advantages and specific object-s obtained with its use, reference should be hadto the accompanying draw,

ings and descriptive matter in which we have illustrated and described a preferred embodiment of the invention.

In the drawings:

Fig. l is a perspective view of the essential parts of a potentiometer instrument:

Fig. 2 is a circuit diagram of a typical potentiometer arrangement;

Fig. 3 is a view of the right hand side plate with parts thereof broken away to move clearly and show the standardizing mechanism;

Fig. 4 is a view of the slide-wire assembly with the standardizing mechanism attached thereto;

Fig. 5 is a view taken on line 55 of Fig. 4, and Fe. 6

Fig. 6 is a. view taken on llflt. 6-45 of Fig. 4 and Fig 5;

Fig. 7 is a top view of a modified form 01 standardizing mechanism;

Fig. 8 is a view looking from the right of Fig. 7; Fig. 9 is a view of the standardizing mechanism 5' and part of the slide-wire assembly looking from the left of Fig. 7;

Fig. 10 is a front view of the battery renewal indicating member;

Fig. ll'is a side view of a multiple record polu tentiometer showing a lock-out mechanism therefor operated by the standardizing mechanism; and

Fig. 12 is a top view of certain linkage of Fig. 11. There is disclosedin Fig. 2 a typical potentiom- 15 eter circuit in which the reference character V distinguishes a substantial constant source of electromotive force, usually a dry cell connected in series with an adjustable resistor RS that may be adjusted to vary the current flow in the circuit which also contains asllde-wire resistor 2|. The normal use of the above described circuit is in measuring the electromotive force of an element such as the thermocouple T, the element being connected in series with a galvanometer I and the slide-wire 2| at a point along the length of the latter to oppose the battery V. The amount of the slide-wire 2| in the latter circuit is varied as may be necessary to bring the galvanometer pointer to zero.

In each operation of the instrument a contact I 9, which is in series with the thermocouple T, is

moved along the slide-wire 2| until the galvanometer pointer occupies its neutral position. In such a, case the potential drop along the slidewire 2| between point MA and the contact I9, is

equel and opposite t the potential drop between this point in the circuit including the battery V.

When the voltage of the thermocouple exceeds or is less than the voltage drop across the resistance 2| between point ZIA and contact IS the galvanometer pointer is displaced from its neutral po sition and the contact I9 is shiftedby the relay mechanism, to be later described, until the pointer resumes its neutral position.

1 While the electromotive force of the battery V is normally constant, its voltage ordinarily diminishes progressively throughout the work life of the cell. While a variation of the voltage source V does not prevent the rebalancing of the potentiometer, in practice an accurate measurement is only obtained by compensating for such voltage variations so as to maintain an approximately constant current flow through the potentiometcr circuit. Such compensation may be effected by moving the contact 35 along the resistthe battery circuit. The adjustment of the contact 35 constitutes a recalibration of the potentiometer, with which the present invention is concerned.

The recalibration action automatically carried out with the instrument herein disclosed, involves a periodic adjustment of the switch lever 3| from a position in which it engages the contact 32, to

insert the thermocouple T into the galvanometer circuit, to a position in which it engages contacts 33 and 34. In the latter position a source of standard volage VS is connected in series with the galvanometer to oppose the voltage drop of tact 35 along the resistance RS until the galvanometer is again in its neutral position, with the voltage sources V and VS equal. After a predetermined number of rebalancing operations during which the contact 35 is being adjusted to its proper position the switch arm- 3| will again be automatically moved into engagement with contact 32 to reinstate thermocouple '1 in series with the galvanometer.

The recording potentiometer instrument shown in perspective in Fig. l, and significant operative parts of which are-illustrated in Fig. 1, includes a galvanometer l, the pointer 2 of which deflects in response to a condition of unbalance in the potentiometer measuring circuit, which may be any well-lmown form including the resistance 2| which may be adjusted to rebalance the potentiometer, The instrument also comprises mechanical relay provisions operated by a constantly rotating' driving motor (not shown) and controlled by the deflection of the galvanometer pointer 2' away from its normal zero position, to periodically rebalance the potentiometercircuit and move a pen or other recorder-carriage 23 along a travelling record strip 26 to record the varying value of the quantity measured on said strip.-

In respect to its recording potentiometer functions, the instrument shown is of the form disclosed in Patent No. 1,946,280, dated February 6, 1934, by Thomas R. Harrison, and in respect to the type of control mechanism employed herein, we make use of certain instrumentalities to be later disclosed.

The mechanism of the instrument of Fig. 1 through which the deflection of the galvanometer pointer 2 controls the adjustments of the recorder carriage 28 and the 'rebalanceof the po tenticmeter circuit on a variation in the quantity or value measured by the galvanometer comprises a pointer engaging and position gauging element 3. The latter is pivotally supported and, in connection with the hereinafter mentioned shaft 6, has a loading tendency which may well be due partlyto spring and partly to gravital action, to turn upward into the position in which one or another of the shoulders 5 of the member 3 engage the pointer 2. The element 8 is engaged by, and turns with the arm 6' of a rock shaft 6. A spring it tends to hold a rocker 8, which is journaled on a pivot. 9, in the position in which the rocker engages an arm I secured to the'shaft 6 and thereby holds the latter in a position in which the shoulders 5 are all below the pointer 2.

A cam II, which is carried by a shaft 12 constantly rotated by the instrument driving motor ance RS to vary the amount of that resistance in through a speed reduction gearing, turns the rocker 8 about its pivot against the action of the spring I 0, once during each revolution. This allows the arm 7 to turn counter-clockwise, as seen in Fig. 1, until the corresponding angular movement of the shaft. 6 is interrupted by the engagement of one or another of the shoulders 5 of the member 3 with the galvanometer pointer Y 2. The shoulders 5 are so arranged that the turning movement of the shaft 6 and arm I, thus permitted, will be greater or less according to the deflective position of the pointer 2 at the time. When the arm I thus turns counter-clockwise, -a lateral projection I of that arm engages and turns a secondary pointer element It into a position corresponding to the then deflection of the pointer 2. The secondary pointer i4 is loosely journaled on the shaft 6, and has a gravitational loading tendency to cum in the clockwise direction as seen in Fig. 1', so that the arm I4 normally bears against the projection I of the arm I.

At the end of each angular adjustment of the secondary pointer l4 into a position corresponding to the then deflection of the galvanometer 2, one or another of the three shoulders ISH, MN and I 5L of a locking member l5 engages the bottom the pointers 2 and I4 occupy their neutral positions, the shoulder I5N of the member l5 comes into locking engagement with the member ll. When the galvanometer pointer 2 has deflected to the right as'seen in Fig. 1, as it does when the actual value of the quantity measured is lower than that indicated by the previously made and still existing potentiometer'adjustment, the secondary pointer I4 is engaged and locked by the shoulder ISL. When the galvanometer pointer deflects in the opposite direction from its neutral position, as it does when the actual value of the quantity measured is higher than that indicated by the existing potentiometer adjustment, the pointer I4 is engaged and locked by the shoulder 15E of the member l5. The locking part I! is given a tendency to move into locking engagement with the secondary pointer H by the spring I0, but is periodically held out of such engagement by the action on its projection [5' of the projection ISA carried by a ratchet lever l8 pivoted at [63.

A spring I60 gives the lever IS a tendency to turn forward in the clockwise direction as seen in Fig. 1, but throughout the major portion of each rotation of the shaft l2, the lever I6 is held in a retracted position by a cam I! carried by said shaft and engaged by the cam follower roll IGD carried by the lever IS. The ratchet lever is operatively connected to two pawls [6E and NF cooperating with a toothed wheel 18. Each of said pawls have a gravital tendency to occupy a position in which it does not engage the teeth of the wheel l8, but one or the other of the pawls is brought into engagement with the teeth of the wheel on each forward or clockwise movement of the lever l6, if the locking part I5 is then at one side or the other of the intermediate or neutral position which it occupied when the galvanometer pointer 2 is in its neutral position.

- The position assumed by the part l5, when in looking engagement with the secondary pointer l4, controls the action of the pawls "SE and [SF by virtue of the fact that the collar or hub portion 15A of the part l5 carries a spring pawl part i moves into the position in which its.

shoulder 15L engages the secondary pointer 14,

- the arm I5B shifts the pawl IBF into operative engagement with the wheel i8, and the latter is then adjusted in the counter-clockwise direction.

The extent of the adiustment then given the wheel I8 is made dependent upon the position of the secondary pointer l4, as said position determines which of the various shoulders of an arm IGG carried by the lever l5 shall then engage a projecting portion A of the secondary pointer l4, and thereby arrest the forward movement of the ratchet lever i6. In the neutral position of the galvanometer .pointerand secondary pointer (the projection A of the latter engages the central shoulder IBG' of the arm IBG and the lever i6 is then held against any operative movement in the clockwise direction. When the secondary pointer position is more or less to one side or the other of its neutral position, the

' portion A engages an upper or lower shoulder on arm IGG more or less distant from the central shoulder IGG, and the lever I6 is then perof a rheostat shaft l9 which is geared to the shaft i8, by gears 36, and 31, on which the wheel I8 is secured. The rotation of the shaft 19 moves a bridging contact 20 along the convolutions 2! of a.- potentiometer resistance helically disposed about the axis of the shaft i9, and thereby varies the amount of said resistance in the potentiometer circuit. The resistance adjustments made in response to a deflection of the galvanometer pointer in one direction away from its neutral position rebalances, or tends to rebalance, the po-- tentiometer circuit and thereby returns. or tends to return, the galvanometer pointer to its neutral position.

The rotation of the wheel i8 adjusts the recorder carrier 23- by virtue of the fact that the teeth of the wheel 18 are in mesh with the teeth of a gear 22a carried by a carriage adjusting shaft 22 which is formed with a thread groove of coarse pitch which receives a cam or mutilated screw thread rib secured to the carriage 23, so that the latter is moved longitudinally of the shaft 22 as the latter is rotated.

The marker carriage 23 comprises a frame portion formed of a single piece of sheet metal cut and bent to form a fiat underbody portion transverse to and through which the shaft 22 extends. two projections 23b, one at each front corner of said body portion which bear against rthe inner edge and upper side of the lower flange of a channel bar or rail 24 forming part-of the instrument framework. In addition, the bodyportion of the carriage frame is provided with a forwardly extending tongue passing beneath the rail 24 and terminating in an uprising pointer or index 23d (see Fig, 3) adapted to cooperate with a scale 24' fastened to the front face of the rail 24 to indicate the position of the pen carriage and the value of the quantity measured and recorded by the instrument.

The record sheet 26 passes over and is given feeding or advancing movements by a record feedroll 21. The latter is intermittently rotated by means of a worm and screw connection between the shaft of the roll 21 and a transverse shaft 28. Shaft 28 is intermittently actuated by means of a ratchet and lever device 30 which is engaged and oscillated by the arm 8 of the rocker 8 on each oscillation of the, latter.

The shaft I9 forms part of the rebalancing mechanism and is journaled in a part 38 that may be formed of some insulating moulded material which is formed with a helical groove on its outer surface to support the slide-wire resistance II. A cylindrical extension on the part 38 at its lower end is formed with circular grooves to support the recalibrating resistance R8. The part Il may be enclosed in; a glass or other suitable casing 39 to protect it from dirt and corrosive fumes. As more clearly shown in- Figs. 4 and 6 the shaft l9 has attached to its upper end the gear 31 and to its lower end a laterally extending arm 40 that supports a bracket 4! in which the contact 20 is adapted to move in engagement with the slidewire 2|. The arrangement is such that as the shaft I9 is rotated the contact 20 will be raised and lowered. as it travels in a helical groove formed by the resistance 2| and a cooperating conductor 42.

Surrounding the shaft I9 and acting as a journal therefor is a tubular shaft 43 that has attached'to its upper end a driving gear 44 and attached to its lower end an angular bracket 45 which supports the contact 35 for movement around the resistance RS. The shaft 43 is jourbaled at its upper and lower end in a bushing 48 hat may be moulded in the part 38. The gear 44 is periodcally rotated to change the position of contact 35 along the resistance RS and thereby recalibrate the instrument, by the potentiometer rebalancing mechanism. The manner in which this is accomplished will now be described.

Rotatably mounted on bushing 46 is a collar 41 which has attached to it a lever 48 that is generally U shaped in form and is provided at its outer end with a socket 49. The socket receives a ball '50 on the upper end of a lever 5| that is journaled for oscillation on the shaft 18'. The lower end of lever Si is provided with an opening 52 that receives a roller 53 carried by one end of 'the lever 8. Therefore, upon each cycle of the instrument rebalancing mechanism the lever 5| is oscillated around sha t l8 to oscillate the lever 48 around bushing 45 by means of the ball and socket joint 49, 50.

The lever 48 has pivotally mounted on it a pawl 55 which is biased in a counteclockwise direction in Fig. 5, by a spring 56, into engagement with a large ratchet 51,-the ratchet being journaled for rotation on bushing 45. The ratchet 51 is rotated one tooth to reach cycle of the instrument and is provided with one deep tooth 58 so that once each revolution thereof the pawl 55 can engage a tooth in a small ratchet 59 which is rotatable on the bushing 45 above the ratchet 61. The ratchet 59 is therefore rotated for a distance of one tooth upon each revolution of the ratchet 51. Holding pawls 60 and 6| are pivoted at 62 on the part 38 and biased toward ratchets 51 and 59 respectively by a spring 63.;

Attached to the ratchet il is a cam 64 having a low portion 94A that has an arc of a distance approximately equal to six ratchet teeth and attached to the ratchet 59 is a disc 65 having a cutout portion 65A. Bearing on the edge of cam 64 is a roller 66 that ismounted near the end of a lever 61 which has an upturned edge 68 bearing on the edge of disc 65. The lever 61 is pivoted at 69 and is biased in a clockwise direction around its pivot by a spring to keep the roller 66 and edge 68 in engagement with the cam and disc respectively.

Also pivoted at 69, above the lever 61 is a second lever H that is resiliently held by a spring 12 so that an extension 1 IA thereof is in engagement with a projection 61A in the form of an eccentric screw on the lever 61. One end of the lever 1| carriesa pair of gears 13 and 14 that are rotatable together and that are adapted to engage respectively with gear 15 attached to shaft l9 and the gear 44 on the tubular shaft 43.-

Attached to the other end of the lever 1! is a link 16 which connects for movement with the lever 1| a' third lever 11 that is pivoted at 18. This lever 11 has 9. turned down portion 11A on one end to act as ahandle and a turned up portion 11B on the other end which normally bears against the gear. 44 to prevent accidental movement thereof. The pivot 18 is a stub shaft which extends through a switch housing 19 on -the part 38 and has attached to it the switch arm3l as well as lever 11..

In the normal operation of the device the parts are positioned as in Fig. 5 with the switch arm 3| in engagement with contact 32, the arm "A in engagement with eccentric screw 61A and the gears 13 and 14 out of mesh with gears 15 and 44 respectively. During the normal operation of the instrument the relay mechanism is measuring the deflection of the galvanometer pointer and adjusting the pen carriage along the chart to make a record of the value of the condition to which the thermocouple T is responsive. Upon each cycle of the instrument the lever 8 moves the lever 48 to rotate ratchet 51 a distance of one tooth. Once during each revolution of ratchet 51 the deep tooth 58 thereof comes under pawl 55 and the ratchet 59 is thereby rotated for a distance of one tooth.

The rotation of ratchet 59 eventually brings the cut-out portion 65A of the disc 65 under edge 68 of lever 61 as shown in Fig. 5. Thereafter during the rotation of cam 64 its low portion 64A will come under roller 66 and permit that roller and its supporting lever 61 to move clockwise in Fig. 5 under the bias of spring 10. As lever 61 moves it will move the lever H to bring gears 13 and 14 into mesh with gears 15 and 44 respectively, and at the same time, through link 16, move lever 11 clockwise to release the brake 11B from gear 44. This same movement rotates shaft 18 and switch arm 3| to bring the switch arm into engagement with contacts 33 and 34.

Thestandard cell VS is now connected across the slide-wire 2|, through the galvanometer I, in opposition to the dry cell V. Thereafter, if the voltage of the dry cell has decreased, the gal- .vanometer will be deflected in accordance with such decrease. The relay mechanism will rotate the gear 31 in accordance with the galvanometer deflection and through the gear train 31, 15, 13, 14 and 44 rotate the tubular shaft 43 to move contact 35 along the standardizing resistance BS in a direction to compensate for the decrease in voltage of the dry 'cell V. The low portion ofcam 64 extends for an are equal to about six to the left in Fig. 4.

tooth 58 will come under pawl 55 so that the I ratchet 5i can be moved and take cut-out portion 65A of disc 65 out from under edge 68. The number ofteeth in each ratchet is computed with respect to the time of the instrument cycle so that the automatic standardizing takes place approximately every thirty minutes.

Provision is also made in the above mechanism to standardize the potentiometer at any time by manually moving the gears 13 and 14. This is accomplished by pressing the part 11A Such movement shifts switch arm 3| into engagement with contacts 33 and 34 and at the same time, through link 16,

moves lever-1| around its pivot against the ten-.

sion of spring 12 to mesh'gears 13 and 15 and gears 14 and 44. The instrument will thereafter standardize itself in the above described manner until such time as lever 11 is returned to its normal position. It is noted that the brake member 113 is used to prevent accidental movement of the gear 44 and therefore accidental rlizigvement of the contact 35 along the resistance There is shown in Figs. 7-1 0 another embodiment of our invention that diifers mainly from the one previously described in that the cam mechanism which determines the time between the standardizing periods is driven at a constant speed through a reduction gear. from the main motor drive shaft instead of by a ratchet mechanism from the rebalancing mechanism.

.As is shown in Fig. 7 the constantly rotating motor shaft [2 is provided with a worm that meshes with a worm wheel 8| fastened to a vertical shaft 82. This shaft extends through a bushing, 82A on the part 38 and is provided on its top with a pinion 83 that meshes withthe larger of two gears 84 and 85 that are journaled for rotation on a bushing 86 which is also mounted on part 38. The gears 84 and 85 mesh respectively with gears 81 and 88 that are mounted for rotation around the bushing 46, as were the ratchets 51 and 59 of the previously described embodiment, and therefore the latter gears are rotated at different speeds. Attached to the gear 81 is a large cam 89 having a cut-out portion 89A and attached to the gear 88 is a smaller cam 90 having a cut-out portion 90A. These cams, when their cut-out portions have a definite relation to each other, serve to permit the recalibrating or standardizing operation to take place in a manner presently to be described.

The tubular shaft 43 that moves the contact 35 along the resistance RS is, ine this case, provided at its upp eim'nd with a gear 9| that meshes with a gear 92 which is mounted for rotation around a shaft 93. Attached to the gear 92 is a gear 94 that meshes with a third gear 95 rotatable around a stud shaft on the end of a lever 96, which lever is also pivoted on the shaft 93. The gear 95 is adapted to mesh with a gear 91 on the shaft I9 so that when the two are in mesh the gear 9! will be driven upon rotation of shaft Hi, to adjust the contact 35. The lever 96 may be moved to engage gears 95 and 91 by pusliing the turned down end 98A of. lever 98 to the left in Fig. 9 or upward in Fig. 7. Movement is transferred from the lever 98 to leves 96 through a link 99 and against the bias of a spring I that normally holds the lever 92 in the position shown in Fig. 7 with its edge in engagement with an eccentric pin IOI. Movement of the lever 98 also turns the shaft 18 to shift contact arm 3| from engagement with contact 32 into engagement with contacts 33 and 34 to connect the standard cell VS in circuit with the galvanometer an removes a brake 983 from the gear 9I.

The lever 96 is automatically shifted to mesh gears 95 and 91 by a lever I02 upon which the pin IN is mounted. This lever I02 is also pivoted on shaft 93 and is biased in a clockwise direction or meshing direction in Fig. 7, by a spring i03 so that its end I04 normally bears on the cam 90 and a roller I 05 on it normally bears on the cam 89. When the cams 89 and 90 rotating at dinerent speeds, are in such relative positions that their low portions are respectively under the roller I05 and end I04 the lever I02 is moved by the spring I03 to bring the gears 95 and 81 into engagement and perform the r'ecalibrating operation.

The operation of this embodiment of the invention is very similar to that of the embodiment disclosed in Figs. 46. The gear 83, driven at a constant speed from the motor shaft I2, drives the gears 81 and 88 and their respective cams 89 and 90 at slightly different rates. When, during their rotation, the lowportions of the cam 89 and 90 come under roller I 05 and end I04 of the lever I02, that lever will be moved clockwise in Fig. 7 by the spring I03 and, through pin IOI and lever 96, will bring gears 95 and 9'! into mesh. This same movement will, through the link 94, move the lever 98 to release a brake from gear 9| and connect the standard cell VS in the galvanometer circuit and across the slide-wire 2i to oppose the battery V. If the voltages of battery V and standard cell VS are not the same the galvanometer will be deflected and the relay mechanism will rotate gear 31 in response thereto. Rotation of gear 31 will, through the gear train 91, 95, 94, 92' and 9|, rotate the shaft 43 and contact 35 to a position along resistance RS until the values of battery V and standard cell VS are equal. The low portions 89A and 90A of the cams are so dimensioned with respect to their speed that enough cycles of the relay mechanism can take place to recaiibrate the circuit before the edge of 89A comes under roller I05 to move the levers I02 and 96 back to their normal positions of Fig. 7.

The instrument can be recalibrated at any time by manually moving the lever 98 clockwise in Fig. 7 and thereby throwing the switch 8| and moving gears 95 and 91 into mesh.

. III, as is best shown in Fig. 10, has attached It is often desirable to have some indication of the value of battery V so that the instrument attendant may be notified when it is necessary to replace the battery with a new one. To this end the gear BI is provided with a downwardly" projecting pin I 06 that is so angularly positioned on the gear with respect to the contact 35 on arm 45 that the position of the pin is an indication of the position of the contact. The position of this pin is then used to set an indicating member. Pivotally mounted on a bushing I01 projecting from the upper surface of part 38 is a lever I08 which has one end in the path of pin I08 and attached to its other end one end of a link I09. The other end of link I 09 is pivoted to the upper end of a crank member H0 that is attached to a shaft III which is suitably joumaled in a side plate of the instrument. The front end of shaft to it a pointer I I2 that moves across a suitable scale II3 fastened to the front of the scale 24'. y

In operation, as the gear 9I turns counterclockwise in Fig. 7, due to adjustments made to the contact arm. the pin I08 will engage lever I08 and rotate it around its pivot. This moves the pointer 2' across. scale H3 and at the time the voltage of battery V has decreased to a point where renewal is necessary the end of pointer I I2 is over the mark on the scale. It is of course,

obvious that an indicator of this type could also be used in connection with the embodiment shown in Figs. 4-6 if desired. To do this it would only be necessary to attach a pin 44. Such a construction has not been shown in the first embodiment solely for the sake of clearness.

When an. automatic standardizing or recalibrati ng mechanism is used on. a' multiple potentiom'eter instrument, or one withwhich records are made of the values of a plurality of conditions, it is necessary to provide some means which will prevent a printing operation from taking place during the recalibrating-periods. The reason for this is because in mostmultiple instruments the printing and switching'operations, the latter of which connects the instrument to another thermocouple, take place either periodically, or after the instrument has reached a balance condition. Therefore, ifthe standardimng period should betaking place when a printing operation occurred an incorrect-value would be recorded for the condition that was being measured prior to the start of the standardizing period, and the switching operation would take place before a true record could be made.

There is shown in Fig. 11 the side plate of a multiple potentiometer with various of the parts removed to move clearly and show a hold-out means forthe printing mechanism. The rebalancing relay may take the form oi that previously described in this application and the printing mechanism may well be of the type shown and described in the application of Coleman B. Moore, Serial Number 224,826 to which no claim is made herein. Enough of the printing mechanism will be described to clearly demonstrate how the mechanism herein may be used to prevent a printing operation from taking place during a standardizing period.

The printing mechanism may consist of any desired type of print hammer or print wheel, but is preferably of the type disclosed in the above mentioned application 224,826 and is mounted on a splined shaft H4 for sliding movement transversely of the instrument. The print wheel is moved to a position above the chart corresponding to the value of the condition being measured by the threaded shaft 22 which is driven through gears 22A and I8 in a manner already described. The printing operation takes place periodically as the instrument reaches a balanced condition.

In order to perform the printing operation a lever I I5 is fastened to the splined shaft Ill and is biased counterclockwise to bring its roller IIS and edge II5A into engagement with the periphered surface of a cam Ill having cut-out portions IIIA. This cam is intermittently rotated by a ratchet wheel II8 to bring its cut-out portions below the edge II 5A so that the lever I I5 may turn counter-clockwise and rotate shaft II4 to perform the printing operation. Attached to I06 to the gear the cam II! for rotation therewith is a disc I I8 and between the disc and cam extends a pair of pins I20 that are so positioned with respect to the portions IIIA thatimmediately after one of the portions II1A comes under edge IIA to permit a printing operation a pin engages a tooth of the wheel I2I to rotate that wheel for a distance of one tooth. Rotation of wheel I 2| is used to switch another thermocouple into the galvanometer circuit and to bring another printing character into printing relation to the chart, all as set forth in the above mentioned application 224,826.

The ratchet H8 is periodically rotated by a pawl I22 can-led on a pawl plate I23 that oscillates around shaft II8A upon which the cam, ratchet and disc are mounted. The pawl plate I23 is oscillated by a link I 24 attached at one end thereto, and at its other end to an armof the lever -8. The arrangement is such that when the instrument is almost in balance the pawl I22 printing position, but when the instrument is further frombalance as when it has Just been switched to a thermocouple, the pawl will not be effective to move the ratchet. This is accomplished in the following manner.

As'has been previously described the position of edge A with respect to the steps on the arm I6G determines the movement of gear I8 and the threaded shaft 22 to position the pen carriage properly above the chart. When the instrument is far enough out of balance for the projection A to engage one of the shoulders of arm I-BG beyond the shoulders "IBJ, a pin ISH will be in the path of an arm 8A formed on the lever 8 to prevent that lever from moving the full length of its clockwise stroke as determined by engagement of its roller 83 and the cut-out portion IIA on cam I I. This limiting of the stroke of lever 8 prevents the plate I23 from moving clockwise enough for pawl I22 to engage the next tooth on ratchet II8. When, however, the instrument is near enough in balance for edge A to engage the shoulders ISJ of the arm IBG the lever I6 will be prevented from moving counterclockwise far enough for the pin I 6H to be under arm 8A. Therefore, during the subsequent cycles of the instrument lever 8 can move its full stroke and pawl I22 will move ratchet II8. The instrument is so designed that after edge I IA engages shoulder IGJ it will be in balance within four cycles, therefore the ratchet H8 is provided with eight teeth and cam II I is provided with two cut-out portions IIIA so that two printing and switching operations occur for each complete revolution thereof.

It is, of course, obvious that more teeth could be formed on the ratchet if desired or that the pin IBH could be omitted so that the ratchet is rotated on each cycle of the instrument. In the latter case it would be best to use only one cutout portion TA and one pin I20 in order that the instrument would be given a longer time between each printing operation. The specific manner in which th printing is accomplished is not material in the present application except insofar as there is provided some means to prevent a printing operation from taking place during recalibrating periods.

Since the recalibrating periods are determined by cams 64 and 65 Or by cams 89 and 90 independently of the printing cycles or the neamess of the instrument to balance, successive recalibrating would normally cause a printing operawill rotate ratchet II8 to bring the cam III to.

tion to occur. To prevent this an L shaped lever I28 pivote on shaft I8, is moved under a pin I26 on lev r 8 during each recalibrating period. This arm prevents lever 8 from making its complete clockwise stroke and thereby prevents the pawl I22 from engaging the next tooth on the ratchet IIB so that the cam II I' and wheel I2I will not be moved. The lever I25'is biased by' ravity and/or a spring in a clockwise, locking 4 direction, but is normally held in its counterclockwise position, as shown in Fig. 11, by engagement between a roller I2'I on its upper end and a cam I28. The cam I28 forms part of a lever I29 which is pivoted at I30 on a bracket attached to the side plate and connected at its other end to an extension-98C of lever 88 (as shown in Fig. 12), or lever II, by a link I3I.

In its operation, as the lever 98 is moved clockwise in Fig. 1-2 to initiate a recalibrating period the lever I29 will also be moved clockwise to permit its cam edge I28 to recede relative to the roller I2'I.- The lever I25 may therefore move clockwise in Fig. 11 until its hooked end is in the path of pin I26 on the lever 8. Thereafter while the instrument is being recalibrated the roller 83 on lever 8 is unable to enter the cut-out portion IIA of cam II and therefore the lever 8 can not move far enough for pawl I22 to rotate ratchet II8. Consequently no printing or switching operation may take place while the instrument is being recalibrated.

From the above description it will'be seen that we have provided a standardizing or recalibratand positive in its to the instrument is the addition thereto of a device for actuating the standardizing mechanism, and this is easily installed.

The mechanism of our invention is versatile enough for any use inasmuch as it may either be operated automatically, or manually by moving the lever TI or lever 98 in the proper direction. By providing an indicator for the battery-con dition the attendant is warned in advance of the need for a new battery and by providing a lockout arm for use on multiple instruments only ac curat recorders are made.

While in accordance with the provisions of the statutes. we have illustrated and described the best form of our invention now known to us, it will be apparent to those skilled in the art that changes may be made in the form of the apparatus disclosed without departing from the spirit of our invention as set forth in the appended claims, and that in some cases certain features of our invention may sometimes be used to advantage without a corresponding use of other features.

Having now described our invention, what we claim as new and desire to secure by Letters Patent is:

1. In a self-balancing measuring instrument of the type wherein there is provided a measuring circuit having a recalibrating resistance and means to adjust the same, the combination of a first rotating ratchet, a first cam rotatable therewith, a second rotating ratchet, a second cam rotatable therewith, means to rotate said'ratchets, a first gear to drive the adjusting means, a mechanical relay, a second gear driven by said mechanical relay, and means responsive to the angular position of said cams to connect said second gear in driving relation with the first.

- 2; In a self-balancing measuring instrument, a deflecting element, a pair of relatively movable members, cyclically operating means to adapted to relatively adjust said members in accordance with deflection of said element, ratchet means operated by said cyclic means and means controlled by said ratchet means to connect said cyclically operating means to said relatively moving members to relatively adjust said members by said cyclically operating means.

3. In a self-balancing measuring instrument the type wherein there is provided a measuring circuit having a source of potential, a measuring resistance, a recallbrating resistance and a galvanometer with a deflecting element; the combination with said element of periodically operated means to efiect adjustments of the measuring resistance depending upon deflection of said element from a normal position, a member tending to move from an inactive position to a position in which it will initiate adjustment ofthe recalibrating resistance by said periodically operated means, means to maintain said member in its inactive position comprising a pair of cam followers on said member, a pair of cams upon which said followers are adapted to bear respectively and intermittently operated means to rotate said cams at different rates.

4. In a measuring instrument,. the combination of a pair of resistances, means to adjust one resistance including a gear, intermittently operated means to rotate said gear, means to adjust the second of said resistances at periodic intervals including a second gear, means to drive said second gear from the first including a pair of 'idler. gears mounted tor rotation together and adapted to be movedinto mesh with said first two gears, cam means rotated by said intermittently operated means, and mechanism controlled by said cam means to regulate movement of said idler gears into and out of mesh with said first two gears.

5. In a self-balancing measuring instrument, the combination of a deflecting element, means to apply a first force to deflect said element, me-

chanical relay means to return said element to a neutral position in response to a deflection thereof, means to apply a second force to cause a deflection of said element, means to alternately connect said force applying means to said element,

ratchet means to operate "said last mentioned.

means, said ratchet means in turn being operated by said mechanical relay, cams connected to and rotatable with said ratchet means, means to ad- Just said element operated by said mechanical relay in response to connection to said element of said second force applying means, said cams operating to control the time said second force is applied to said element.

WALTER G. 'I'RUMBOWER. EDWIN C. WIEGMANN. COLEMAN B. MOORE.

Patel 1t No. 2,315,682.,

7 CERTIFICATE oFqomgT'Ion;

' of the above numbered. patent requiring corregtioh 0.5 foliovi a; Page 7 first tors Patent should-be rend with this corre ction column, line 5, claim 2', liter the word "mama" strike out "to" andjline 9,

claim 2, after "means to insdrf --perio dicnily--'; and that the a8.1d Let- I therein tint .th'e ine m conrd m' to there cor d of the' can o in the Putqnt Office.

Signed and. sealed t hia 25th day or-Hay, A. 'D.- 191;}.

(Seal) I Acting Canmisaioner or Plt'zexitm 

